US1522294A - Electrical testing system - Google Patents

Description

Jan, 6, 1925.

H. FLETCHER ELECTRI CAL TESTI NG SYSTEM Filed Jan. 1922 AMPLIFIER RECTIFIER hue/725m Harvey f7e/2h/f W W if 4M w 47/ Patented Jan. 6, 1925.

LEZLZi-d HARVEY FLETCHER, 01 NEY'V YORK, N. '35., ASSIG-NGB T0 WESTERN ELECTRIC COll/I- PANY, INCORPORATE-D, 0F YORK, N. S1, A CQR-EORATIGN OF NEW YORK.

ELECTRICAL TESTING sYsTEM.

Application filed January 7, 1922. Serial No. 527,581.

To all 10/107 t may concern.

Be it known that I, HARVEY FLETCHER, a citizen of the United States, residing at New Yorlo in the county of New York, State of New York, have invented certain new and useful Improvements in Electrical Testing Systems, of which the following is a full, clear, concise, and exact description.

This invention relates in general to elec trical testing systems and particularly to sys tems for testing the eliiciency of lines for the transmission of electrical currents.

One great inconvenience encountered in testing the efiiciency of transmission lines is that it has usually been found necessary to locate the source of testing currents at one end of the line and the measuring de vices at the other. Since neither the measuring devices nor the source of testing current are conveniently carried a bout it may readily be seen that a system wherein both the measuring apparatus and the source of testing current are controlled from the same station, possesses distinct advantages. One such system is disclosed in patent to Fred H. Best 1,414,397, lllay 2, 1922. In that patent there is described a system for testing telephone subscribers lines in which current is impressed on the line, wires employed in a so-called simplex circuit, to actuate a standardized telephone receiver at the subscribers station. The simplex circuit consists of the wires of the subscribers loop in parallel with each other and connected at both ends to ground. The telephone receiver is then held at a predetermined distance from either the transmitter or receiver of the subscribers telephone set. The sound energy of the standard receiver is thus used to generate electrical waves on the metallic line, which may be measured accurately at the central station. A comparison of the amount of energy originally transmitted 'and that received and measured provides an indication of the eiiiciency of the subscribers line and station.

An object of the invention to provide a measuring system of the class described, which is accurate, convenient and simple to operate; and which will measure the trans mitting and receiving efficiency of the subscribers station.

Another object is to provide a system wherein the transmission efficiency of a line is measurable independently of the efiiciency of the instruments provdied at a subscribers station, and in which such n'ieasur-ements may be made independently of the length of the line.

To accomplish these objects there is provided an inductive coupling of high primary impedance at the remote end of the line, which couples the simplex circuit with the metallic circuit. The current thus transmitted'from the simplex circuit to the metallic circuit is measured at the originating station and the transmission efliciency deter mined by comparison with a standaro arbitrarily established. At the testing station source of alternating current is associated with the simplexed line circuit through a pair of accurately balanced impedances. The line is also bridged through a pair of high impedances to a voltmeter which is adjusted to indicate a constant voltage. This arrangement insures the same amount of agitation in the testing receiver for dif ferentlengths of loops, as will be explained later.

The invention may be more completely understood by reference to the following description in conjunction with the drawing, which diagrammatically represents a form of the invention as used for the measurement of the efliciency of telephone transmission lines and apparatus Referring to the drawing, 1 and 2 represent atelephone line terminating at a subscribers station comprising a call bell 3, a transmitter at, a receiver 5, an induction coil 6, and a. condenser 7, obstructing the flow of direct current through call bell 3.

This arrangement of station apparatus is a common one used in centralized battery systems. Current for line 1 2, is supplied from a source 8 shunted by a condensert), through inductances 10 and 1].. p 7

A source of alternating current 12 is provided, of a frequency within the range of voice vibrations and preferably about 1000 cycles since it is at suchfrequencies only that the transmission efficiency is of interest in telephone practice. If desired this source may have a band of frequencies within the range of voice frequency. Current source 12 is associated with a pair of leads l3 and to c innect leads impede leads iii 2:

voltmeter cordence it is pe sioof loops a consterled by the high as will be cxplsi essential when conipz ii trsnsniittc This result coiiiplished by T431551 biting! generator 12 by n ice 18. A tii o-pole SNll'i h 13 and hi the lines 1 and 2. respec At the subscribei."s ste potei tioin-e" is nroridcd witi the sides oli tion there nected in shunt with the inc 7 52 s set of apparatus which includes a for connection witl vely, of the line; two outer ool s d and the inner pole both lends Ll.- end 2i balanced, iinpedences 23, JllOO ohnis leads 20 and 21 and l, respecl'i switch 22 the yith lc connecting through uccuratelf sch 01? which is of the order cfi ectiye r \sistanee; low in'ipedsi former ondary 25L ci'innerl or, outer contects of switch and a pedance transformer pm L llGCii .lln lfl unce ieceiver 2o not wit 0 l and site with the i. e of s it the central station grounded shield trmistorne v. c i i primar is in c rcuit wit e. anal i i. A condenser 28 is symmetricinterposed between two hal es oi the primary 0t 17 ans- .iornicr 2'? sin prevents the flow o" direct current therethr ugh from the source scri By the arrangement of apparatus decircuit and :i 1-. ciii 'Tnc simp A circuit incluces the current source it? inipedances l5 13% end a sides (5 the line 1 sndsi impedzinces 23 center pol oi switch 22, receiver or priinar c 22, and

inc" upon the position thence l'QlCi JllLX h: The metallic circuit .itch lean primer tliormer 27,, condens r lead switch il 9,

side 2 of. the line 0 i other elements dependins upon the position of sii .-h 2; and the n siibch hook one Vi epressed and switch 22 is in its upper position, and hence the only additional element in the metallic circuit is the low impedance secondary 24 of the transformer comprising windings 24 and in testing the transmitting and receiving of the subscribers station switch 1 wer position and points mil are connected together by the switchand hence the metallic circuit does cc iiiclude transformer secondary 2 3;, but does iii lude transmitter 4: and the primary cii' induction coil 6. This represents the taken by most of the oscilgenerated at the subscril)cii"s the metallic circuit 15 16 and inductsuch comparatively little current The shunts to by impedances 11 are of iin 'iedance that comparatively .ows through them.

current amnieter 29 associated till a suitable amplifying and recti'liying is connected with the seconds y transformer 27, through a switch wire potentiometer 82 a switch 34;, potentiometer 35, and leads icncing; a test of a line.

switches are first thrown down. Current then iio'e's from source 12 through switche lTP-QClQUlC-(S 38, primary of the inductive to ground. induced current in the secondary oi transformer flows through switch 19, load 13. orimenv of 'zii'isi orinei- $257 condenser 28, iced ii. e l to the secondary of transformer 3 Switch 33 is thrown to contact i *ith its lower and switch 31 to its lower pole. ilur induced in the secondary of transform- .en lows through lead potention'v 33 to tap switch 33, potentiour 9:2 to a tap 4 1. switch 3 zin'iplityiini' rcctityin means 30, which may lie oi well known type. and theretore for '-ie sulze of simplicity has not been shown n zininicter 529i and lead 57 to second err 27. This current causes an -.on ammcter 2,9 which is noted re reference in connection with the C It also indicates iaioiint oi current which transformer 39 duplicate tians'l orniei' comprising 1s and will generrte with 71:;10 loss or zero impedance in the line I. The o: lElV he edjiiistcd to suitable value h}? t ot potentioine l8. voltmeter n obtaining; 21 suitable prelii'ninarr that the impedance of the line wires with esnect to the impedance oi pier-I circuit but is mini.-

iic iinpcdance oi the re t oi =c .1 :iiii, F r er -temple tew Hfj' the sending" or receii/in eflic-iencv of the SlliJ- scribers set, switch 22 is in its lower position and the current from source 12 traverses high impedances 15, line wires 1 and 2 in parallel, high impedances 23 and high impedance receiver 226. lVith the lengths of subscribers loops met in practice, the impedance of line wires 1 and 2 in parallel is negligible in effect with respect to the combined impedance of resistances 15, 23 and receiver 26 as connected. Hence, for practical purposes, the length of the loop will not affect the amount of current delivered to receiver 26 by a constant voltage as indicated by' voltmeter 17, or in other words, receiver 26 will give a constant volume of sound output regardless of the length of the loo-p. Similarly the impedance of primary winding is high, and the current delivered to it is not affected by the length of loops which are met in practice.

It should be noted, however, that resistances 15 and 23 and high impedance receiver 26 (or winding 25) are not a. part of the metallic circuit and the impedance of wind- .ing 2%: and primary of transformer 27 being low, the impedance of the line wires is commensurate with the entire impedance of the metallic circuit. For this reason there is no difficulty in measuring the attenuating effec' of the line wires upon the current delivered from the subscribers station over the metal lic circuit to the primary of transformer 2'7.

The subscribers line 1, 2 is then tested by movin switches 19, 22, 31 and 33 to their upper posit-ions and switch 34 to its center position. The sin'iplex circuit is then completed through. transformer primary 25 to ground, and the metallic circuit is completed through transformer secondary 2-1, as above described. In this testthe switchhool: 51 is kept depressed and the impedance of the ringer 3 in series with condenser 7 is so high that only a negligible portion of the current induced in the transformer secondary 24 traverses this path. CIHTQIIiJlS induced as before in the secondary of transformer 27 and takes the path including lead 36, potentiometer 35, tap (t0. switch 5544:. switch 9-3, potentiometer 32, to an adjustable tap 4:2, switch 31, element 30, and lead 37. A reading is obtained on ammeter 29 as before, and tap $2 is adjusted until this reading is the same as that previously obtained using transformer A scale associated with adiustah-lc tap 42 is preferably provided havinc, 1' zero point corresponding to tap 41, to indicate the position which tap 42 would oc cupy if the line has no loss in transmission ciliciency, The deviation of the resulting position from this point indicates the loss or gain in efficiency in the line being measured. In this test. the transmission loss of the line, exclusive of the subscribers station, is indicated.

in testing the efficiency of the linethe final displacement of tap 42 from tape]. is a measure of the ratio of th'e'curremis delivered to the primary of transformer 27 when employing transformer 39 and that comprising the windings 241 and 25.--. This allows the scale associated with tap 42. to be calibrated to read directly the efficiency of the transmission line in terms of miles of standard cable, or other suitable trans mission unit.

If the current delivered to the primary of transformer 27 from transformer second-' ary 24 is less than that delivered to-the primary of transformer 27 by the secondary of transformer 39, the subscribers line causes a loss, which is denominated a loss in efiiciency and may be evaluated in terms of minus transmission units such as miles of standard cable. In case the current de livered by transformer secondary 24; is greater than that delivered by the secondary of transformer 39 there is a gain which would be evaluated in positive transmission units.

Transmission efficiency such as efficiency in miles of standard cable, which may be either positive or negative, should not be confused with the ordinary power efficiency, which is the ratio of the energy-delivered by a piece of apparatus to the energy supplied to the apparatus. The basis for expressing the transmission efficiency of-a piece of telephone equipment or a telephone line as n miles of standard cable isthat the piece of equipment or line causes are-duction in the power receivedover the circuit in which it is placed, which is the same as the differcnce in the amounts of power at two points n miles apart along a lengthof standard cable; Ifrurrent is being supplied over a transmission line and points land 2 which are n miles apart are considered, the ratio of the amount of power at these two points is equal to the square of theratio of the" currents, or to the square of the ratio of the voltages, at these two points and this ratio can be expressed in terms of the attenuation per mile of the line, viz.

whereP, I and E equal power, current and voltage respectively and the subscript showswhether the quantity is at a polnt 1 or point 2. a is the attenuation constant per mile of the line. The square root of the ratio of the amount of power received over a telephone circuitw'ith a piece of equipment in the circuit to the amount of power received when the piece of equipment is replaced 1 a standard piece is sometimes called the equivalent current ratio and can be used as a measure of the change produced in the circuit) From this equivalent.

current ratio a corresponding attenuation can be obtained. This attenuation divided by the attenuation per mile of standard cable for a particular frequency gives the where at a certain frequency P, is the amount of power received over a telephone circuit with a piece of equipment, and P is the amount of power at the same frequency received if the piece of equipment is replaced by a standard piece. a is the attenuation constant corresponding to this equivalent current ratio. Therefore, us-

ing a, the attenuation constant per mile of standard cable for the same frequency (from the equation on the preceding page) as the denominator of a fraction of which a is the numerator, gives the eflic'iency of the piece of apparatus in miles of standard cable;

a V12. 5 efliciency in miles of standard cable.

In determining the efficiency of a subscribers loop the standard would be taken as a Zero loop and hence the efhciency of the loop would be the number of miles of standard cable which would cause an attenuation either positive or negative, equal to that caused by the subscribers loop. This would be expressed as miles positive or miles negative, as the case might be. In the case of the efliciency of transmitters and receivers comparison would be made to a'standard transmitter or a receiver, as the case might be.

It is seen from the foregoing equation that if the current ratio is known, the equivalent miles of standard cable can be obtained without the incorporation of any other quantity than the attenuation constant per mile of standard cable for a particular frequency and, since this known, the scale associated with tap 42 may be calibrated to read directly in terms of miles of standard cable, or other suitable transmission unit. If the final setting is obtained with tap 42, above tap 41 there is a loss in eliiciency equal to the number of miles of standard cable indicated, whereas if the final setting is obtained with tap 42 below tap 41, there is a gain in efliciency equal to the indicated number of miles of standard cable.

The next test to be made is for receiving efficiency at the subscribers station. For this test, switch 22 is thrown to its position connecting receiver 26 in the simplex circuit and disconnecting the transformer primary 25 and secondary 24. The switchhook is placed in its upper position, thus connecting 50 and 51. Receiver 26, which under the conditions mentioned, emits the same intensity of sound for all loop lengths met with in practice, is held at a predeter mined distance from receiver 5 such that the force exerted upon the diaphragm of all receivers thus tested, may be uniform. The magneto current thus generated induces a current in the metallic circuit above described through the medium of induction coil 6. Switch 34 is thrown to the position shown in the drawing. In this position of switch 34 less resistance of element 35 is included in the current measuring circuit than was included in the previous test, and the included resistances in each case are made to be in inverse proportion to the relative generating efficiency of standard receivers and the transformer comprising windings 24 and 25. Induced current then flows from the secondary of transformer 27 through lead 36, switch 34, switch 33, potentiometer 32 to adjustable tap 42, switch 31, element 30, and lead 37. The position of tap 42 is adjusted as before until the initial reading of ainmeter 29 is again ob tained. The deviation of the resulting position of tap 42 from the position indicating standard efficiency as above referred to, indicates in this case the discrepancy in receiving efliciency of the subscribers station. Due to the shift of switch 34 the displacement of tap 42 gives the e'fliciency to the same scale as in the line test.

To test the transmitting efficiency of the subscribers station, receiver 26 is held a standard distance from the transmitter 4, thus causing the same force to be exerted upon all tested transmitters. Oscillations set up in the metallic circuit as before, cause induced current in the secondary of transformer 27, which follows the path through lead 36, potentiometer 35 to a tap 43, switch 34 belng thrown to its lower position, switch 33, tap 42, switch 31, element 30, and lead 37. As in the two cases above described, the ammeter indication should remain the same as originally set when tap 42 is adjusted to the point indicating standard efficiency, and the amount of adjustment necessary to obtain such an indication constitutes a measure of the deviation from standard efliciency. With switch 34 in its lower position the amount of resistance 35 in the current measuring circuit as compared to the amount in the circuit when transformer 39 was employed is in inverse proportion to the relative generating efficiencies of standard transmitters and the transformer comprising windings 24 and 25, which is a duplicate of transformer 39.

The system as above described provides a very convenient means for rapidly testing all phases of the efficiency of a subscriber line. It is an improvement over the method of the F. H. Best patent referred to above, since from its results, more accurate deductions may be may as to conditions causing failure of performance. In a receiver test the results obtained include the combined efficiency of the receiver and the transmission line and likewise in the transmitter test the result given by the position of tap 42 indicates the combined efficiency of the transmitter and the line. These combined efliciencies have been termed the receiving and transmitting efiiciencies of the subscribers station, respectively. However, in the line test the efliciency of the line alone was obtained and hence this can be deducted from the results obtained in the transmitter and the receiver tests to obtain the transmitting and receiving efiiciencies of the subset alone. Also the test may be made more rapidly and with less chance of error.

The calibration of the measuring portion of the circuit by means of transformer 39, suffices for a number of tests and when once accomplished, is used only as a check upon the accuracy of the test at future times.

That is claimed is:

1. In an electrical testing system, a metallic line circuit to be tested, a simplex circuit superimposed on said line circuit, a source of testing current associated with the simplex circuit, inductive means energized by current in the simplex circuit to generate current in the metallic circuit, and

means to measure the current flowing in the metallic circuit.

2. In an electrical testing system, a metallic line circuit to be tested, a simplex circuit, superimposed on said line circuit, a source of testing current associated with the simplex circuit, inductive means energized by current in the simplex circuit to energized by current from said source to apply definite amounts of power to said line, said receiver, and said transmitter; and 7 means to measure the resulting current delivered over the line to a point near'said source, to indicate to the same scale the transmission efficiency of said line and the receiving and sending transmission efficiency of said station.

In witness whereof, I hereunto subscribe my name this 6th day of January A. D., 1922.

HARVEY FLETCHER.

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